Expression of cloned bovine adrenal rhodanese

A cDNA for the enzyme rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1) has been cloned from a bovine adrenal library. An initiator methionine codon precedes the amino-terminal amino acid found in the isolated protein. Rhodanese is synthesized in the cytoplasm and transferred to the mitochondrial matrix. Thus, any amino-terminal sequence required for organelle import is retained in the mature protein. Furthermore, the DNA sequence shows that there are three additional amino acids, Gly-Lys-Ala, at the carboxyl terminus that are not found by protein sequencing. Additionally, comparison of the published amino acid sequence with that encoded by the open reading frame revealed three differences in the amino acid sequence. Comparison of the bovine and chicken liver sequences shows an overall level of 70% sequence homology, but there is complete identity of all residues that have been implicated in the function of the enzyme. When two mammalian cells, cos-7 and 293 cells, were transiently transfected with a plasmid containing the rhodanese coding region, rhodanese activity in lysates increased approximately 20-fold. Fluorograms of denaturing polyacrylamide gels detected a large increase in a polypeptide that co-migrated with the native protein and reacted with anti-rhodanese antibodies. Nondenaturing gels showed two active species that co-migrated with the two major electrophoretic forms purified by current procedures. Escherichia coli, transformed with a plasmid containing the rhodanese coding region, showed a 15-fold increase in rhodanese activity over baseline values. When the E. coli recombinant protein was analyzed on a nondenaturing gel, only one species was observed that co-electrophoresed with the more electropositive variant seen in purified bovine liver rhodanese. This single variant could be converted by carboxypeptidase B digestion to a form of the enzyme that co-migrated with the more electronegative species isolated from bovine liver. Thus, two major, enzymatically active electrophoretic variants, commonly observed in mammalian cells, can be accounted for by carboxyl-terminal processing without recourse to other post-translational modifications.     

Comparative genomics of Bacillus thuringiensis phage 0305φ8-36: defining patterns of descent in a novel ancient phage lineage

Background

Members of the familyIridoviridae can cause severe diseases resulting in significant economic and environmental losses. Very little is known about how iridoviruses cause disease in their host. In the present study, we describe the re-analysis of theIridoviridae family of complex DNA viruses using a variety of comparative genomic tools to yield a greater consensus among the annotated sequences of its members.

Results

A series of genomic sequence comparisons were made among, and between theRanavirus andMegalocytivirus genera in order to identify novel conserved ORFs. Of these two genera, theMegalocytivirus genomes required the greatest number of altered annotations. Prior to our re-analysis, the Megalocytivirus species orange-spotted grouper iridovirus and rock bream iridovirus shared 99% sequence identity, but only 82 out of 118 potential ORFs were annotated; in contrast, we predict that these species share an identical complement of genes. These annotation changes allowed the redefinition of the group of core genes shared by all iridoviruses. Seven new core genes were identified, bringing the total number to 26.

Conclusion

Our re-analysis of genomes within theIridoviridae family provides a unifying framework to understand the biology of these viruses. Further re-defining the core set of iridovirus genes will continue to lead us to a better understanding of the phylogenetic relationships between individual iridoviruses as well as giving us a much deeper understanding of iridovirus replication. In addition, this analysis will provide a better framework for characterizing and annotating currently unclassified iridoviruses.     

AT-rich islands in genomic DNA as a novel target for AT-specific DNA-reactive antitumor drugs

Interstrand cross-links at T(A/T)4A sites in cellular DNA are associated with hypercytotoxicity of an anticancer drug, bizelesin. Here we evaluated whether these lethal effects reflect targeting critical genomic regions. An in silico analysis of human sequences showed that T(A/T)4A motifs are on average scarce and scattered. However, significantly higher local motif densities were identified in distinct minisatellite regions (200-1000 base pairs of approximately 85-100% AT), herein referred to as "AT islands." Experimentally detected bizelesin lesions agree with these in silico predictions. Actual bizelesin adducts clustered within the model AT island naked DNA, whereas motif-poor sequences were only sparsely adducted. In cancer cells, bizelesin produced high levels of lesions (approximately 4.7-7.1 lesions/kilobase pair/microM drug) in several prominent AT islands, compared with markedly lower lesion levels in several motif-poor loci and in bulk cellular DNA (approximately 0.8-1.3 and approximately 0.9 lesions/kilobase pair/microM drug, respectively). The identified AT islands exhibit sequence attributes of matrix attachment regions (MARs), domains that organize DNA loops on the nuclear matrix. The computed "MAR potential" and propensity for supercoiling-induced duplex destabilization (both predictive of strong MARs) correlate with the total number of bizelesin binding sites. Hence, MAR-like AT-rich non-coding domains can be regarded as a novel class of critical targets for anticancer drugs.     

Characterization of lytic Pseudomonas aeruginosa bacteriophages via biological properties and genomic sequences

Pseudomonas aeruginosa is an important cause of infections, especially in patients with immunodeficiency or diabetes. Antibiotics are effective in preventing morbidity and mortality from Pseudomonas infection, but because of spreading multidrug-resistant bacterial strains, bacteriophages are being explored as an alternative therapy. Two newly purified broad host range Pseudomonas phages, named vB_Pae-Kakheti25 and vB_Pae-TbilisiM32, were characterized as candidates for use in phage therapy. Morphology, host range, growth properties, thermal stability, serology, genomic sequence, and virion composition are reported. When phages are used as bactericides, they are used in mixtures to overcome the development of resistance in the targeted bacterial population. These two phages are representative of diverse siphoviral and podoviral phage families, respectively, and hence have unrelated mechanisms of infection and no cross-antigenicity. Composing bactericidal phage mixtures with members of different phage families may decrease the incidence of developing resistance through a common mechanism.     

Structure of the Marine Siphovirus TW1: Evolution of Capsid-Stabilizing Proteins and Tail Spikes

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Extensive movement of LINES ONE sequences in beta-globin loci of Mus caroli and Mus domesticus.

LINES ONE (L1) is a family of movable DNA sequences found in mammals. To measure the rate of their movement, we have compared the positions of L1 elements within homologous genetic loci that are separated by known divergence times. Two models that predict different outcomes of this analysis have been proposed for the behavior of L1 sequences. (i) Previous theoretical studies of concerted evolution in L1 have indicated that the majority of the 100,000 extant L1 elements may have inserted as recently as within the last 3 million years. (ii) Gene conversion has been proposed as an alternative to a history of prolific recent insertions. To distinguish between these two models, we cloned and characterized two embryonic beta-globin haplotypes from Mus caroli and compared them with those of M. domesticus. In 9 of 10 instances, we observed an L1 element to be present in one chromosome and absent at the same site in a homologous chromosome. This frequency is quantitatively consistent with the known rate of concerted evolution. Therefore, we conclude that gene conversion is not required for concerted evolution of the L1 family in the mouse. Furthermore, we show that the extensive movement of L1 sequences contributes to restriction fragment length polymorphism. L1 insertions may be the predominant cause of restriction fragment length polymorphisms in closely related haplotypes.     

Construction and mapping of recombinant plasmids used for the preparation of DNA fragments containing the Escherichia coli lactose operator and promoter.

Three DNA restriction fragments of established sequence containing the Escherichia coli lac genetic controlling regions were cloned. In each case a recombinant plasmid was constructed which was suitable for the subsequent large scale purification of the lac fragment. A 789-base pair HindII fragment, containing the lac operator, promoter, and cyclic AMP receptor protein binding site, was ligated into the single HindII site of the amplifiable plasmid minicolicin E1 DNA (pVH51). A 203-base pair Hae III fragment containing the same genetic sites was ligated into the single Eco RI site of pVH51 which had been "filled in" by the Micrococcus luteus DNA polymerase. Thus, the lac fragment was inserted between two Eco RI sites. Plasmids containing multiple copies of this Eco RI fragment were then constructed. A 95-base pair Alu I fragment containing the lac promoter and operator was cloned similarly. Also, the 203-base pair fragment was cloned into the Eco RI site of pVH51 using a 300-base pair linker fragment (isolated by RPC-5 column chromatography) which permitted retention of its Hae III ends. Mapping studies on pVH51 DNA with a number of DNA restriction endonucleases, including Alu I, Taq I, and Hpa II, are described.     

Mus Spretus Line-1s in the Mus Musculus Domesticus Inbred Strain C57bl/6j Are from Two Different Mus Spretus Line-1 Subfamilies

A LINE-1 element, L1C105, was found in the Mus musculus domesticus inbred strain, C57BL/6J. Upon sequencing, this element was found to belong to a M. spretus LINE-1 subfamily originating within the last 0.2 million years. This is the second spretus-specific LINE-1 subfamily found to be represented in C57BL/6J. Although it is unclear how these M. spretus LINE-1s transferred from M. spretus to M. m. domesticus, it is now clear that at least two different spretus LINE-1 sequences have recently transferred. The limited divergence between the C57BL/6J spretus-like LINE-1s and their closest spretus ancestors suggests that the transfer did not involve an exceptionally long lineage of sequential transpositions.